//! `ra_hir_expand` deals with macro expansion. //! //! Specifically, it implements a concept of `MacroFile` -- a file whose syntax //! tree originates not from the text of some `FileId`, but from some macro //! expansion. pub mod db; pub mod ast_id_map; pub mod name; pub mod hygiene; pub mod diagnostics; pub mod builtin_derive; pub mod builtin_macro; pub mod quote; use std::hash::Hash; use std::sync::Arc; use ra_db::{salsa, CrateId, FileId}; use ra_syntax::{ algo, ast::{self, AstNode}, SyntaxNode, SyntaxToken, TextUnit, }; use crate::ast_id_map::FileAstId; use crate::builtin_derive::BuiltinDeriveExpander; use crate::builtin_macro::BuiltinFnLikeExpander; #[cfg(test)] mod test_db; /// Input to the analyzer is a set of files, where each file is identified by /// `FileId` and contains source code. However, another source of source code in /// Rust are macros: each macro can be thought of as producing a "temporary /// file". To assign an id to such a file, we use the id of the macro call that /// produced the file. So, a `HirFileId` is either a `FileId` (source code /// written by user), or a `MacroCallId` (source code produced by macro). /// /// What is a `MacroCallId`? Simplifying, it's a `HirFileId` of a file /// containing the call plus the offset of the macro call in the file. Note that /// this is a recursive definition! However, the size_of of `HirFileId` is /// finite (because everything bottoms out at the real `FileId`) and small /// (`MacroCallId` uses the location interner). #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct HirFileId(HirFileIdRepr); #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] enum HirFileIdRepr { FileId(FileId), MacroFile(MacroFile), } impl From for HirFileId { fn from(id: FileId) -> Self { HirFileId(HirFileIdRepr::FileId(id)) } } impl From for HirFileId { fn from(id: MacroFile) -> Self { HirFileId(HirFileIdRepr::MacroFile(id)) } } impl HirFileId { /// For macro-expansion files, returns the file original source file the /// expansion originated from. pub fn original_file(self, db: &dyn db::AstDatabase) -> FileId { match self.0 { HirFileIdRepr::FileId(file_id) => file_id, HirFileIdRepr::MacroFile(macro_file) => { let lazy_id = match macro_file.macro_call_id { MacroCallId::LazyMacro(id) => id, }; let loc = db.lookup_intern_macro(lazy_id); loc.kind.file_id().original_file(db) } } } /// If this is a macro call, returns the syntax node of the call. pub fn call_node(self, db: &dyn db::AstDatabase) -> Option> { match self.0 { HirFileIdRepr::FileId(_) => None, HirFileIdRepr::MacroFile(macro_file) => { let lazy_id = match macro_file.macro_call_id { MacroCallId::LazyMacro(id) => id, }; let loc = db.lookup_intern_macro(lazy_id); Some(loc.kind.node(db)) } } } /// Return expansion information if it is a macro-expansion file pub fn expansion_info(self, db: &dyn db::AstDatabase) -> Option { match self.0 { HirFileIdRepr::FileId(_) => None, HirFileIdRepr::MacroFile(macro_file) => { let lazy_id = match macro_file.macro_call_id { MacroCallId::LazyMacro(id) => id, }; let loc: MacroCallLoc = db.lookup_intern_macro(lazy_id); let arg_tt = loc.kind.arg(db)?; let def_tt = loc.def.ast_id?.to_node(db).token_tree()?; let macro_def = db.macro_def(loc.def)?; let (parse, exp_map) = db.parse_macro(macro_file)?; let macro_arg = db.macro_arg(macro_file.macro_call_id)?; Some(ExpansionInfo { expanded: InFile::new(self, parse.syntax_node()), arg: InFile::new(loc.kind.file_id(), arg_tt), def: InFile::new(loc.def.ast_id?.file_id, def_tt), macro_arg, macro_def, exp_map, }) } } } /// Indicate it is macro file generated for builtin derive pub fn is_builtin_derive(&self, db: &dyn db::AstDatabase) -> Option> { match self.0 { HirFileIdRepr::FileId(_) => None, HirFileIdRepr::MacroFile(macro_file) => { let lazy_id = match macro_file.macro_call_id { MacroCallId::LazyMacro(id) => id, }; let loc: MacroCallLoc = db.lookup_intern_macro(lazy_id); let item = match loc.def.kind { MacroDefKind::BuiltInDerive(_) => loc.kind.node(db), _ => return None, }; Some(item.with_value(ast::ModuleItem::cast(item.value.clone())?)) } } } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct MacroFile { macro_call_id: MacroCallId, } /// `MacroCallId` identifies a particular macro invocation, like /// `println!("Hello, {}", world)`. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub enum MacroCallId { LazyMacro(LazyMacroId), } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct LazyMacroId(salsa::InternId); impl salsa::InternKey for LazyMacroId { fn from_intern_id(v: salsa::InternId) -> Self { LazyMacroId(v) } fn as_intern_id(&self) -> salsa::InternId { self.0 } } impl From for MacroCallId { fn from(it: LazyMacroId) -> Self { MacroCallId::LazyMacro(it) } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct MacroDefId { // FIXME: krate and ast_id are currently optional because we don't have a // definition location for built-in derives. There is one, though: the // standard library defines them. The problem is that it uses the new // `macro` syntax for this, which we don't support yet. As soon as we do // (which will probably require touching this code), we can instead use // that (and also remove the hacks for resolving built-in derives). pub krate: Option, pub ast_id: Option>, pub kind: MacroDefKind, } impl MacroDefId { pub fn as_call_id(self, db: &dyn db::AstDatabase, kind: MacroCallKind) -> MacroCallId { db.intern_macro(MacroCallLoc { def: self, kind }).into() } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub enum MacroDefKind { Declarative, BuiltIn(BuiltinFnLikeExpander), // FIXME: maybe just Builtin and rename BuiltinFnLikeExpander to BuiltinExpander BuiltInDerive(BuiltinDeriveExpander), } #[derive(Debug, Clone, PartialEq, Eq, Hash)] pub struct MacroCallLoc { pub(crate) def: MacroDefId, pub(crate) kind: MacroCallKind, } #[derive(Debug, Clone, PartialEq, Eq, Hash)] pub enum MacroCallKind { FnLike(AstId), Attr(AstId), } impl MacroCallKind { pub fn file_id(&self) -> HirFileId { match self { MacroCallKind::FnLike(ast_id) => ast_id.file_id, MacroCallKind::Attr(ast_id) => ast_id.file_id, } } pub fn node(&self, db: &dyn db::AstDatabase) -> InFile { match self { MacroCallKind::FnLike(ast_id) => ast_id.with_value(ast_id.to_node(db).syntax().clone()), MacroCallKind::Attr(ast_id) => ast_id.with_value(ast_id.to_node(db).syntax().clone()), } } pub fn arg(&self, db: &dyn db::AstDatabase) -> Option { match self { MacroCallKind::FnLike(ast_id) => { Some(ast_id.to_node(db).token_tree()?.syntax().clone()) } MacroCallKind::Attr(ast_id) => Some(ast_id.to_node(db).syntax().clone()), } } } impl MacroCallId { pub fn as_file(self) -> HirFileId { MacroFile { macro_call_id: self }.into() } } /// ExpansionInfo mainly describes how to map text range between src and expanded macro #[derive(Debug, Clone, PartialEq, Eq)] pub struct ExpansionInfo { expanded: InFile, arg: InFile, def: InFile, macro_def: Arc<(db::TokenExpander, mbe::TokenMap)>, macro_arg: Arc<(tt::Subtree, mbe::TokenMap)>, exp_map: Arc, } pub use mbe::Origin; impl ExpansionInfo { pub fn call_node(&self) -> Option> { Some(self.arg.with_value(self.arg.value.parent()?)) } pub fn map_token_down(&self, token: InFile<&SyntaxToken>) -> Option> { assert_eq!(token.file_id, self.arg.file_id); let range = token.value.text_range().checked_sub(self.arg.value.text_range().start())?; let token_id = self.macro_arg.1.token_by_range(range)?; let token_id = self.macro_def.0.map_id_down(token_id); let range = self.exp_map.range_by_token(token_id)?.by_kind(token.value.kind())?; let token = algo::find_covering_element(&self.expanded.value, range).into_token()?; Some(self.expanded.with_value(token)) } pub fn map_token_up( &self, token: InFile<&SyntaxToken>, ) -> Option<(InFile, Origin)> { let token_id = self.exp_map.token_by_range(token.value.text_range())?; let (token_id, origin) = self.macro_def.0.map_id_up(token_id); let (token_map, tt) = match origin { mbe::Origin::Call => (&self.macro_arg.1, self.arg.clone()), mbe::Origin::Def => { (&self.macro_def.1, self.def.as_ref().map(|tt| tt.syntax().clone())) } }; let range = token_map.range_by_token(token_id)?.by_kind(token.value.kind())?; let token = algo::find_covering_element(&tt.value, range + tt.value.text_range().start()) .into_token()?; Some((tt.with_value(token), origin)) } } /// `AstId` points to an AST node in any file. /// /// It is stable across reparses, and can be used as salsa key/value. // FIXME: isn't this just a `Source>` ? pub type AstId = InFile>; impl AstId { pub fn to_node(&self, db: &dyn db::AstDatabase) -> N { let root = db.parse_or_expand(self.file_id).unwrap(); db.ast_id_map(self.file_id).get(self.value).to_node(&root) } } /// `InFile` stores a value of `T` inside a particular file/syntax tree. /// /// Typical usages are: /// /// * `InFile` -- syntax node in a file /// * `InFile` -- ast node in a file /// * `InFile` -- offset in a file #[derive(Debug, PartialEq, Eq, Clone, Copy, Hash)] pub struct InFile { pub file_id: HirFileId, pub value: T, } impl InFile { pub fn new(file_id: HirFileId, value: T) -> InFile { InFile { file_id, value } } // Similarly, naming here is stupid... pub fn with_value(&self, value: U) -> InFile { InFile::new(self.file_id, value) } pub fn map U, U>(self, f: F) -> InFile { InFile::new(self.file_id, f(self.value)) } pub fn as_ref(&self) -> InFile<&T> { self.with_value(&self.value) } pub fn file_syntax(&self, db: &impl db::AstDatabase) -> SyntaxNode { db.parse_or_expand(self.file_id).expect("source created from invalid file") } } impl InFile<&T> { pub fn cloned(&self) -> InFile { self.with_value(self.value.clone()) } } impl InFile> { pub fn transpose(self) -> Option> { let value = self.value?; Some(InFile::new(self.file_id, value)) } } impl InFile { pub fn ancestors_with_macros( self, db: &impl crate::db::AstDatabase, ) -> impl Iterator> + '_ { std::iter::successors(Some(self), move |node| match node.value.parent() { Some(parent) => Some(node.with_value(parent)), None => { let parent_node = node.file_id.call_node(db)?; Some(parent_node) } }) } } impl InFile { pub fn ancestors_with_macros( self, db: &impl crate::db::AstDatabase, ) -> impl Iterator> + '_ { self.map(|it| it.parent()).ancestors_with_macros(db) } } impl InFile { pub fn descendants(self) -> impl Iterator> { self.value.syntax().descendants().filter_map(T::cast).map(move |n| self.with_value(n)) } pub fn syntax(&self) -> InFile<&SyntaxNode> { self.with_value(self.value.syntax()) } }